Rational invariant subspace approximations with applications Hasan, Mohammed A. ; Azimi-Sadjadi, Mahmood R. ; Hasan, Ali A. "This work was supported in part by the Office of Naval Research [ONR32ITS] under Grant N61331-94-K-0018." Subspace methods such as MUSIC, Minimum Norm, and ESPRIT have gained considerable attention due to their superior performance in sinusoidal and direction-of-arrival (DOA) estimation, but they are also known to be of high computational cost. In this paper, new fast algorithms for approximating signal and noise subspaces and that do not require exact eigendecomposition are presented. These algorithms approximate the required subspace using rational and power-like methods applied to the direct data or the sample covariance matrix. Several ESPRIT- as well as MUSIC-type methods are developed based on these approximations. A substantial computational saving can be gained comparing with those associated with the eigendecomposition-based methods. These methods are demonstrated to have performance comparable to that of MUSIC yet will require fewer computation to obtain the signal subspace matrix. Colorado State University. Libraries 2000 text ; image application/pdf ECEmra00046.pdf FACFECEN100526ARTI eng c2000 IEEE
Rational invariant subspace approximations with applications
Hasan, Mohammed A. ; Azimi-Sadjadi, Mahmood R. ; Hasan, Ali A.
"This work was supported in part by the Office of Naval Research [ONR32ITS] under Grant N61331-94-K-0018."
Subspace methods such as MUSIC, Minimum Norm, and ESPRIT have gained considerable attention due to their superior performance in sinusoidal and direction-of-arrival (DOA) estimation, but they are also known to be of high computational cost. In this paper, new fast algorithms for approximating signal and noise subspaces and that do not require exact eigendecomposition are presented. These algorithms approximate the required subspace using rational and power-like methods applied to the direct data or the sample covariance matrix. Several ESPRIT- as well as MUSIC-type methods are developed based on these approximations. A substantial computational saving can be gained comparing with those associated with the eigendecomposition-based methods. These methods are demonstrated to have performance comparable to that of MUSIC yet will require fewer computation to obtain the signal subspace matrix.
Colorado State University. Libraries
2000
text ; image
application/pdf
ECEmra00046.pdf
FACFECEN100526ARTI
eng
c2000 IEEE